Protein biosynthesis changes in Trypanosoma cruzi induced by supra-optimal temperature

Research progress on the composition and function of parasite-derived exosomes

Parasites use excretory-secretory pathways to communicate with the host. Characterization of exosomes within the excretory-secretory products reveal by which parasites manipulate their hosts. Parasite derived exosomes provide a mechanistic framework for protein and miRNAs transfer. Transcriptomics and proteomics of parasite exosomes identified a large number of miRNAs and proteins being utilized by parasites in their survival, reproduction and development. Characterization of proteins and miRNAs in parasite secreted exosomes provide important information on host-parasite communication and forms the basis for future studies. In this review, we summarize recent advances in isolation and molecular characterization (protein and miRNAs) of parasite derived exosomes.

The heat shock proteins of Trypanosoma cruzi

Trypanosoma cruzi is the causal agent of Chagas' disease, a debilitating disorder affecting millions of people in several countries. A flagellated protozoan parasite, T. cruzi has a complex life cycle that involves infecting an insect and a mammalian host. During its life cycle, the parasite undergoes several kinds of stress, prominent among which is heat stress. To deal with this environmental challenge, molecular chaperones and proteases, also known as heat shock proteins (HSPs), are induced as part of the stress response. Several families of HSPs are synthesized by T. cruzi, including members of the major HSP classes such as HSP70, HSP90, HSP100, HSP40, chaperonins and small HSPs, and these proteins show conserved and unique features. In this review we describe these proteins and the corresponding gene expression patterns and discuss their relevance to the biology of the parasite.

Expression and localization of Trypanosoma cruzi hsp60

A 60-kDa heat shock protein (hsp60) is involved in mitochondrial protein folding and assembly of oligomeric protein complexes in the mitochondrial matrix. Here we report the isolation of Trypanosoma cruzi hsp60 cDNAs, the determination of the organization and chromosomal location of the genes, and the assessment of the heat-regulated expression and subcellular location of the protein. T. cruzi hsp60 is encoded by a multigene family organized in two allelic direct tandem arrays on a chromosome of 1.6 Mb. The regulation of hsp60 expression by heat is complex. While the hsp60 mRNA level is 6-fold higher at 37 degrees C than at either 26 degrees C, the hsp60 protein level remains essentially constant across all temperatures examined. Further analysis of the protein by two-dimensional immunoblotting revealed the existence of multiple isoforms that, with increasing temperature, shift in relative abundance from the more basic to the more acidic. A combination of immunofluorescence microscopy and cell fractionation was used to show that hsp60 is distributed throughout the matrix of the mitochondrion--a location distinct from that of the 70-kDa mitochondrial hsp, mtp70, which is associated with the kinetoplast.

Hsp70 in parasites: as an inducible protective protein and as an antigen

The heat shock (HS) response is a general homeostatic mechanism that protects cells and the entire organism from the deleterious effects of environmental stresses. It has been demonstrated that heat shock proteins (HSP) play major roles in many cellular processes, and have a unique role in several areas of cell biology, from chronic degenerative diseases to immunology, from cancer research to interaction between host and parasites. This review deals with the hsp70 gene family and with its protein product, hsp70, as an antigen when pathogens infect humans. Members of HSP have been shown to be major antigens of many pathogenic organisms when they experience a major temperature shift upwards at the onset of infection and become targets for host B and T cells.

Conservation of heat-shock proteins in Trypanosoma cruzi

Heat shock is an integral part of the life cycle of Trypanosoma cruzi. Here, Edson Rondinelli reviews the parasite's response to stress.

The biology of the heat shock response in parasites

The heat shock response is a general homeostatic mechanism that protects cells and the entire organism from the deleterious effects of environmental stress. It has been shown that heat shock proteins play major roles in many cellular processes and have a unique role in several areas of cell biology, from chronic degenerative diseases to immunology and from cancer research to interactions between host and parasite. In this review, Bruno Maresca and Luisella Carratu deal with some of the unique characteristics of the heat shock response in parasitic organisms.

Effect of elevated environmental temperature on the antibody response of mice to Trypanosoma cruzi during the acute phase of infection

When held at 36 degrees C, Trypanosoma cruzi-infected C3H mice survive an otherwise lethal infection with significantly decreased parasitemia levels and enhanced immune responsiveness. Treatment of T. cruzi-infected mice with the immunosuppressive agent cyclophosphamide indicated that the positive effects of increased environmental temperature were primarily due to enhancement of immunity. A parasite-specific, enzyme-linked immunosorbent assay and immunoblot analysis were used to examine the effect of elevated environmental temperature on the production of anti-T. cruzi antibodies. Both the reactivity and diversity of anti-T. cruzi antibodies were found to be lower in infected mice held at 36 degrees C than in infected mice held at room temperature. However, reactivity and diversity could be enhanced by vaccination with culture forms of the parasite.

HSP 70 gene expression in Trypanosoma cruzi is regulated at different levels

The level of HSP 70 mRNA is altered in Trypanosoma cruzi cells incubated at supra-optimal temperatures: the total amount of this RNA per cell is increased at 37 degrees C, and slightly decreased at 40 degrees C relative to its level at 29 degrees C. However, its amount is greater in the polysomes at either temperature. The relative increase of this RNA is larger in the polysomes fraction than it is in the total RNA. In addition the level of HSP 70 protein in heat-shocked cells is greater than would be expected from the recruitment of HSP 70 mRNA in the polysomal fraction. Taken together the data are interpreted as indicating that at 37 degrees C and 40 degrees C the HSP 70 gene regulation in T. cruzi involves both the selective accumulation of the HSP 70 mRNA in the polysomes and its preferential translation. At 37 degrees C, in addition, an increase in the total amount of this template is observed in the cells.

Changes in the antigenic profile of Leishmania parasites following shifts in temperature

We have examined by immunoblotting the antigen profiles of Leishmania parasites which have undergone upward shifts in ambient temperature during culture. Parasites in the promastigote insect vector stage were grown to stationary growth phase at 25 degrees C, and then further cultured at the 37 degrees C temperature experienced in the mammalian host. Changes in the immunoblot profiles of the parasites occurred within one day of culture at mammalian ambient temperature. Serum antibodies from patients with active Leishmania infections showed reactivity with antigenic determinants of greater than Mr 38,000 that were expressed by parasites at 37 degrees C, and which were not comparably observed on immunoblots of 25 degrees C cultured organisms. The promastigotes of Leishmania species which cause either cutaneous or visceral leishmaniasis express differing forms of the 37 degrees C induced high molecular weight determinants, however, these molecules express cross-reactive epitopes. Previous studies have suggested that temperature may play a role in the differentiation process between the insect and host life cycle stages of Leishmania. Our results suggest that the antigenic profile of Leishmania parasites may also be affected by the expression of products from temperature sensitive biosynthetic pathways.

Extracellular amastigote-like forms of Leishmania panamensis and L. braziliensis. II. Stage- and species-specific monoclonal antibodies

Immunochemical evidence, employing monoclonal antibodies, shows that the forms of L. braziliensis complex axenically grown at elevated temperature are amastigote-like. The monoclonal antibodies were raised against membrane proteins of amastigote-like forms, strains of both L. panamensis (WR442) and L. braziliensis (M5052), which were grown axenically. The specificities of these antibodies were examined by indirect radioimmune binding assay, indirect immunofluorescent assay and Western blot analyses. Two distinct groups of monoclonal antibodies were obtained and their specificities were consistent with the 3 methods used. Four antibodies are specific for the species L. panamensis and react with both developmental stages. Six antibodies specifically recognize amastigote-like forms grown at elevated temperature and intracellular amastigotes of both L. panamensis (WR442) and L. braziliensis (M5052). These monoclonal antibodies do not bind to promastigotes of these species, nor to promastigotes of any other species of Leishmania. Therefore these antibodies are specific for amastigotes of L. panamensis (WR442) and L. braziliensis (M5052), and suggest that immunochemically both amastigote forms (culture and macrophage) are developmentally very close, if not identical. The molecules associated with the amastigote-specific antigenic determinants consist of a Mr 12-kD component and a heterogeneous component (Mr from 50 kD to greater than 200 kD); these molecules appear to be identical for both amastigote-like forms and amastigotes isolated from macrophages.

Trypanosoma cruzi: an in vitro cycle of cell differentiation in axenic culture

The operation of an in vitro cycle of cell differentiation of Trypanosoma cruzi in axenic culture was obtained. When epimastigote forms, grown in LIT medium, were transferred to a modified LIT medium (E. Chiari, 1981, "Diferenciação do Trypanosoma cruzi em cultura." Ph.D. dissertation, Universidade Federal de Minas Gerais, Brazil), metacyclic trypomastigotes were generated. The latter, upon treatment with fresh human serum, and subsequent incubation in LIT medium gave origin to clusters of spheromastigote cells. The spheromastigotes were resistent to lysis mediated by the complement system and possess a morphology shown by optical and electron microscopy to be very similar to spheromastigotes derived from tissues of infected vertebrates. Blood-like trypomastigotes, or epimastigotes, could be obtained from spheromastigotes depending on the incubation conditions: at high serum concentration (55%) at 37 C, blood-like trypomastigotes were generated; by aging or heating (37 C), at low serum concentration (10%), epimastigotes were formed, closing the whole sequence of cell differentiation of T. cruzi. The molecular characterization of the different cell forms by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of metabolic pulse labeled proteins showed that the in vitro differentiated cells were distinct, not only by morphological criteria, but by differential gene expression as well. All the forms described could be obtained in large amounts (6 x 10(7) to 1 x 10(8)/ml), making it possible to perform preparative biochemical, molecular biological, and immunological experiments.